Abstract
The amount and patterning of precipitation beneath vegetation is determined by throughfall and stemflow. Throughfall is the portion of precipitation that falls through, or drips from, the canopy; whereas, stemflow is the portion that drains down the stem. This chapter briefly synthesises throughfall and stemflow methods, data and major drivers of variability from all studies returned from Web of Science that reported relative annual or seasonal throughfall and stemflow (% of precipitation across the canopy) to date: 644 observations spanning broad climate (boreal, temperate, Mediterranean, subtropical and tropical) and plant types (forests, shrublands, croplands and grasslands) around the globe. Relative throughfall was greatest for forests followed by shrubs > crops > grasses; whereas, relative stemflow was greatest for grasses followed by crops > shrubs > forests. This synthesis identified challenges to integrating net precipitation into large-scale (regional-to-global) hydrologic and climate processes and estimates, including: (1) under-sampling at sites; (2) lacking data for solid and mixed precipitation events’ throughfall and stemflow; (3) very few throughfall and stemflow observations for herbaceous vegetation (compared to woody plants) despite croplands and grasslands representing 11% and 27% of the land surface, respectively, as well as understory herbaceous vegetation being present in nearly all forests; and (4) the current focus on fine-scale drivers of highly localized patterns.
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References
Aboal J, Morales D, Hernández M, Jiménez M (1999) The measurement and modelling of the variation of stemflow in a laurel forest in Tenerife, Canary Islands. J Hydrol 221(3–4):161–175
Aboal JR, Saavedra S, Hernández-Moreno JM (2015) Edaphic heterogeneity related to below-canopy water and solute fluxes in a Canarian laurel forest. Plant Soil 387(1–2):177–188
Abrahamsen G, Horntvedt R, Tveite B (1977) Impacts of acid precipitation on coniferous forest ecosystems. Water Air Soil Pollut 8(1):57–73
Ahmadi MT, Attarod P, Mohadjer MRM, Rahmani R, Fathi J (2009) Partitioning rainfall into throughfall, stemflow, and interception loss in an oriental beech (Fagus orientalis Lipsky) forest during the growing season. Turk J Agric For 33(6):557–568
Alexandratos N, Bruinsma J (2012) World agriculture towards 2030/2050: the 2012 revision. ESA Working paper FAO, Rome
Aussenac G (1968) Interception des précipitations par le couvert forestier. Ann Sci Forest 25(3):135–156. https://doi.org/10.1051/forest/19680302
Badri W, Gauquelin T (1998) The hydrological cycle and changes of soil water storage in a thuriferous juniper (Juniperus thurifera L.) stand in the Moroccan High Atlas Mountains. In: Chalise S, Hermann A, Khanal N, Lang H, Molnar L, Pokhrel A (eds) Conference on ecohydrology of high mountain areas, Kathmandu, Nepal, pp 315–321
Bales RC, Hopmans JW, O’Geen AT, Meadows M, Hartsough PC, Kirchner P, Hunsaker CT, Beaudette D (2011) Soil moisture response to snowmelt and rainfall in a Sierra Nevada mixed-conifer forest. Vadose Zone J 10(3):786–799
Beard J (1962) Rainfall interception by grass. S Afr For J 42(1):12–15
Bellot J, Escarre A (1998) Stemflow and throughfall determination in a resprouted Mediterranean holm-oak forest. In: Annales des sciences forestières, vol 7. EDP Sciences, pp 847–865
Bergkvist B, Folkeson L (1995) The influence of tree species on acid deposition, proton budgets and element fluxes in south Swedish forest ecosystems. Ecol Bullet:90–99
Bialkowski R, Buttle JM (2015) Stemflow and throughfall contributions to soil water recharge under trees with differing branch architectures. Hydrol Process 29(18):4068–4082. https://doi.org/10.1002/hyp.10463
Bornmann L, Mutz R (2015) Growth rates of modern science: a bibliometric analysis based on the number of publications and cited references. J Assoc Inf Sci Technol 66(11):2215–2222
Brauman KA, Freyberg DL, Daily GC (2010) Forest structure influences on rainfall partitioning and cloud interception: a comparison of native forest sites in Kona, Hawai’i. Agric For Meteorol 150(2):265–275. https://doi.org/10.1016/j.agrformet.2009.11.011
Bruijnzeel L, Mulligan M, Scatena FN (2011) Hydrometeorology of tropical montane cloud forests: emerging patterns. Hydrol Process 25(3):465–498
Bryant ML, Bhat S, Jacobs JM (2005) Measurements and modeling of throughfall variability for five forest communities in the southeastern US. J Hydrol 312(1–4):95–108. https://doi.org/10.1016/j.jhydrol.2005.02.012
Bui EN, Box JE (1992) Stemflow, rain throughfall, and erosion under canopies of corn and sorghum. Soil Sci Soc Am J 56(1):242–247
Butler D, Huband N (1985) Throughfall and stem-flow in wheat. Agric For Meteorol 35(1–4):329–338
Calder IR (1990) Evaporation in the Uplands. Wiley
Cantú Silva I, González Rodríguez H (2001) Interception loss, throughfall and stemflow chemistry in pine and oak forests in northeastern Mexico. Tree Physiol 21(12–13):1009–1013
Cape J, Brown A, Robertson S, Howson G, Paterson I (1991) Interspecies comparisons of throughfall and stemflow at three sites in northern Britain. For Ecol Manage 46(3–4):165–177
Cappellato R, Peters NE (1995) Dry deposition and canopy leaching rates in deciduous and coniferous forests of the Georgia Piedmont: an assessment of a regression model. J Hydrol 169(1–4):131–150
Carlyle-Moses D, Laureano JF, Price A (2004) Throughfall and throughfall spatial variability in Madrean oak forest communities of northeastern Mexico. J Hydrol 297(1–4):124–135
Carlyle-Moses DE (2004) Throughfall, stemflow, and canopy interception loss fluxes in a semi-arid Sierra Madre Oriental matorral community. J Arid Environ 58(2):181–202. https://doi.org/10.1016/s0140-1963(03)00125-3
Carlyle-Moses DE, Si Iida, Germer S, Llorens P, Michalzik B, Nanko K, Tischer A, Levia DF (2018) Expressing stemflow commensurate with its ecohydrological importance. Adv Water Resour 121:472–479
Chang SC, Matzner E (2000) The effect of beech stemflow on spatial patterns of soil solution chemistry and seepage fluxes in a mixed beech/oak stand. Hydrol Process 14(1):135–144
Courchesne F, Hendershot W (1988) Cycle annuel des éléments nutritifs dans un bassin-versant forestier: contribution de la litière fraîche. Can J For Res 18(7):930–936
Crockford R, Richardson D (2000) Partitioning of rainfall into throughfall, stemflow and interception: effect of forest type, ground cover and climate. Hydrol Process 14(16–17):2903–2920
Davies-Barnard T, Valdes P, Jones C, Singarayer J (2014) Sensitivity of a coupled climate model to canopy interception capacity. Clim Dyn 42(7–8):1715–1732
Dawson TE (1998) Fog in the California redwood forest: ecosystem inputs and use by plants. Oecologia 117(4):476–485
De Ploey J (1982) A stemflow equation for grasses and similar vegetation. CATENA 9(1–2):139–152
De Schrijver A, Geudens G, Augusto L, Staelens J, Mertens J, Wuyts K, Gielis L, Verheyen K (2007) The effect of forest type on throughfall deposition and seepage flux: a review. Oecologia 153(3):663–674
Dolman A (1987) Summer and winter rainfall interception in an oak forest. Predictions with an analytical and a numerical simulation model. J Hydrol 90(1–2):1–9
Dunkerley D (2014a) Stemflow on the woody parts of plants: dependence on rainfall intensity and event profile from laboratory simulations. Hydrol Process 28(22):5469–5482. https://doi.org/10.1002/hyp.10050
Dunkerley D (2014b) Stemflow production and intrastorm rainfall intensity variation: an experimental analysis using laboratory rainfall simulation. Earth Surf Proc Land 39(13):1741–1752. https://doi.org/10.1002/esp.3555
Ford E, Deans J (1978) The effects of canopy structure on stemflow, throughfall and interception loss in a young Sitka spruce plantation. J Appl Ecol:905–917
Foster NW (1974) Annual macroelement transfer from Pinus banksiana Lamb. forest to soil. Can J For Res 4(4):470–476
Frangi JL, Lugo AE (1985) Ecosystem dynamics of a subtropical floodplain forest. Ecol Monogr 55(3):351–369
Freedman B, Prager U (1986) Ambient bulk deposition, throughfall, and stemflow in a variety of forest stands in Nova Scotia. Can J For Res 16(4):854–860
Friesen J, Bawain A, de Jong S, Hildebrandt A (2010) Acoustic throughfall measurements in a semiarid cloud forest, Dhofar, Oman: first results. In: AGU fall meeting abstract
Friesen J, Köhler A (2014) Analysis of splash loss for different throughfall trough designs. In: EGU general assembly conference abstracts
Friesen J, Lundquist J, Van Stan JT (2015) Evolution of forest precipitation water storage measurement methods. Hydrol Process 29(11):2504–2520. https://doi.org/10.1002/hyp.10376
Frost EE, Levia DF (2014) Hydrologic variation of stemflow yield across co-occurring dominant canopy trees of varying mortality. Ecohydrology 7(2):760–770. https://doi.org/10.1002/eco.1397
Garcia-Estringana P, Alonso-Blázquez N, Alegre J (2010) Water storage capacity, stemflow and water funneling in Mediterranean shrubs. J Hydrol 389(3–4):363–372
García-Santos G, Bruijnzeel L (2011) Rainfall, fog and throughfall dynamics in a subtropical ridge top cloud forest, National Park of Garajonay (La Gomera, Canary Islands, Spain). Hydrol Process 25(3):411–417
Germer S, Werther L, Elsenbeer H (2010) Have we underestimated stemflow? Lessons from an open tropical rainforest. J Hydrol 395(3–4):169–179. https://doi.org/10.1016/j.jhydrol.2010.10.022
Gerrits AMJ, Pfister L, Savenije HHG (2010) Spatial and temporal variability of canopy and forest floor interception in a beech forest. Hydrol Process 24(21):3011–3025. https://doi.org/10.1002/hyp.7712
Ghorbani S, Rahmani R (2009) Estimating of interception loss, stemflow and throughfall in a natural stand of oriental Beech (Shastkalateh forest)
Gill D (1975) Influence of white spruce trees on permafrost-table microtopography, Mackenzie River Delta. Can J Earth Sci 12(2):263–272
Godoy R, Oyarzún C, Bahamondes J (1999) Flujos hidroquímicos en un bosque de Nothofagus pumilio en el Parque Nacional Puyehue, sur de Chile. Revista Chilena de Historia Natural 72:579–594
Godoy R, Oyarzún C, Gerding V (2001) Precipitation chemistry in deciduous and evergreen Nothofagus forests of southern Chile under a low-deposition climate. Basic Appl Ecol 2(1):65–72. https://doi.org/10.1078/1439-1791-00037
González-Martínez TM, Williams-Linera G, Holwerda F (2017) Understory and small trees contribute importantly to stemflow of a lower montane cloud forest. Hydrol Process 31(5):1174–1183. https://doi.org/10.1002/hyp.11114
Gordon D, Coenders-Gerrits A, Van Stan Ii JT (2018) Net rainfall partitioning by herbaceous plants in a Pinus palustris understory. In: American Geophysical Union Fall Meeting, Washington, D.C
Guswa AJ, Spence CM (2012) Effect of throughfall variability on recharge: application to hemlock and deciduous forests in western Massachusetts. Ecohydrology 5(5):563–574. https://doi.org/10.1002/eco.281
Hakimi L, Sadeghi SMM, Van Stan JT, Pypker TG, Khosropour E (2018) Management of pomegranate (Punica granatum) orchards alters the supply and pathway of rain water reaching soils in an arid agricultural landscape. Agr Ecosyst Environ 259:77–85
Hallett J, Mason BJ (1958) The influence of temperature and supersaturation on the habit of ice crystals grown from the vapour. Proc R Soc Lond A 247(1251):440–453
Hamdan K, Schmidt M (2012) The influence of bigleaf maple on chemical properties of throughfall, stemflow, and forest floor in coniferous forest in the Pacific Northwest. Can J For Res 42(5):868–878
Harzing A-W, Alakangas S (2016) Google Scholar, Scopus and the Web of Science: a longitudinal and cross-disciplinary comparison. Scientometrics 106(2):787–804
Heartsill-Scalley T, Scatena FN, Estrada C, McDowell WH, Lugo AE (2007) Disturbance and long-term patterns of rainfall and throughfall nutrient fluxes in a subtropical wet forest in Puerto Rico. J Hydrol 333(2–4):472–485. https://doi.org/10.1016/j.jhydrol.2006.09.019
Hedstrom N, Pomeroy J (1998) Measurements and modelling of snow interception in the boreal forest. Hydrol Process 12(10–11):1611–1625
Herwitz SR (1985) Interception storage capacities of tropical rainforest canopy trees. J Hydrol 77(1–4):237–252
Herwitz SR (1986) Infiltration-excess caused by stemflow in a cyclone-prone tropical rainforest. Earth Surf Proc Land 11(4):401–412
Herwitz SR, Levia Jr DF (1997) Mid‐winter stemflow drainage from bigtooth aspen (Populus grandidentata Michx.) in central Massachusetts. Hydrol Process 11(2):169–175
Hildebrandt A, Al Aufi M, Amerjeed M, Shammas M, Eltahir EA (2007) Ecohydrology of a seasonal cloud forest in Dhofar: 1. Field experiment. Water Resour Res 43(10)
Hörmann G, Branding A, Clemen T, Herbst M, Hinrichs A, Thamm F (1996) Calculation and simulation of wind controlled canopy interception of a beech forest in Northern Germany. Agric For Meteorol 79(3):131–148
Huber A, Iroumé A, Bathurst J (2008) Effect of Pinus radiata plantations on water balance in Chile. Hydrol Process Int J 22(1):142–148
Ibrahim M, Rapp M, Lossaint P (1982) Economie de l’eau d’un écosystème à Pinus pinea L. du littoral méditerranéen. In: Annales des Sciences Forestières, vol 3. EDP Sciences, pp 289–306
Iida SI, Shimizu T, Kabeya N, Nobuhiro T, Tamai K, Shimizu A, Ito E, Ohnuki Y, Abe T, Tsuboyama Y (2012) Calibration of tipping-bucket flow meters and rain gauges to measure gross rainfall, throughfall, and stemflow applied to data from a Japanese temperate coniferous forest and a Cambodian tropical deciduous forest. Hydrol Process 26(16):2445–2454
Ilek A, Kucza J, Morkisz K (2017) Hygroscopicity of the bark of selected forest tree species. iForest Biogeosci For 10(1):220–226. https://doi.org/10.3832/ifor1979-009
Jefferies R, MacKerron D (1985) Stemflow in potato crops. J Agric Sci 105(1):205–207
Johnson MS, Lehmann J (2006) Double-funneling of trees: stemflow and root-induced preferential flow. Ecoscience 13(3):324–333
Johnson R (1990) The interception, throughfall and stemflow in a forest in highland Scotland and the comparison with other upland forests in the UK. J Hydrol 118(1–4):281–287
Keim RF, Link TE (2018) Linked spatial variability of throughfall amount and intensity during rainfall in a coniferous forest. Agric For Meteorol 248:15–21. https://doi.org/10.1016/j.agrformet.2017.09.006
Keim RF, Skaugset AE (2004) A linear system model of dynamic throughfall rates beneath forest canopies. Water Resour Res 40(5). https://doi.org/10.1029/2003wr002875
Klamerus-Iwan A, Błońska E (2018) Canopy storage capacity and wettability of leaves and needles: the effect of water temperature changes. J Hydrol 559:534–540
Krämer I, Hölscher D (2009) Rainfall partitioning along a tree diversity gradient in a deciduous old-growth forest in Central Germany. Ecohydrology 2(1):102–114. https://doi.org/10.1002/eco.44
Krutzsch H (1863) Die zu forstlichen Zwecken eingerichteten meteorologischen Stationen sind die Resultate der Deobachtnngen im Jahre 1863. Tharandter forstliches Jahrbuch 16:216–226
Lacombe G, Valentin C, Sounyafong P, De Rouw A, Soulileuth B, Silvera N, Pierret A, Sengtaheuanghoung O, Ribolzi O (2018) Linking crop structure, throughfall, soil surface conditions, runoff and soil detachment: 10 land uses analyzed in Northern Laos. Sci Total Environ 616:1330–1338
Law F (1957) Measurement of rainfall, interception and evaporation losses in a plantation of sitka spruce trees. In: Paper presented at the Compl. Rend. Assoc. Intern. Hydrologic Sci., Toronto, Canada
Lawson ER (1967) Throughall and stemflow in a pine-hardwood stand in the Ouachita Mountains of Arkansas. Water Resour Res 3(3):731–735
Lazerjan MS (2012) Hydrochemistry of rainfall and stemflow of Juglans regia Linn and Cupressus sempervirens L. Var. Fastigiata in the North of Iran. Ecopersia 1(1):85–98
Lei R, Shang L, Tang Z (1994a) The influence of human activities on hydrological functions of a Quercus aliena forest. Studies on forest ecosystems. Northeast Forestry University Press, Harbin, pp 235–244
Lei R, Zhang Y, Dang K (1994b) A study on hydrological effects of forest in Qinling Mountains Forest Region. In: Zhou X (ed) Studies on forest ecosystems. Northeast Forest University Press, Harbin, pp 223–234
Levia DF (2004) Differential winter stemflow generation under contrasting storm conditions in a southern New England broad-leaved deciduous forest. Hydrol Process 18(6):1105–1112. https://doi.org/10.1002/hyp.5512
Levia DF, Frost EE (2003) A review and evaluation of stemflow literature in the hydrologic and biogeochemical cycles of forested and agricultural ecosystems. J Hydrol 274(1–4):1–29
Levia DF, Frost EE (2006) Variability of throughfall volume and solute inputs in wooded ecosystems. Prog Phys Geogr 30(5):605–632. https://doi.org/10.1177/0309133306071145
Levia DF, Germer S (2015) A review of stemflow generation dynamics and stemflow-environment interactions in forests and shrublands. Rev Geophys 53(3):673–714
Levia DF, Herwitz SR (2005) Interspecific variation of bark water storage capacity of three deciduous tree species in relation to stemflow yield and solute flux to forest soils. CATENA 64(1):117–137. https://doi.org/10.1016/j.catena.2005.08.001
Levia DF, Hudson SA, Llorens P, Nanko K (2017) Throughfall drop size distributions: a review and prospectus for future research. Wiley Interdisc Rev Water 4(4):e1225
Levia DF, Keim RF, Carlyle-Moses DE, Frost EE (2011) Throughfall and stemflow in wooded ecosystems. In: Forest hydrology and biogeochemistry. Springer, pp 425–443
Levia DF, Michalzik B, Näthe K, Bischoff S, Richter S, Legates DR (2015) Differential stemflow yield from European beech saplings: the role of individual canopy structure metrics. Hydrol Process 29(1):43–51. https://doi.org/10.1002/hyp.10124
Levia DF, Underwood SJ (2004) Snowmelt induced stemflow in northern hardwood forests: a theoretical explanation on the causation of a neglected hydrological process. Adv Water Resour 27(2):121–128. https://doi.org/10.1016/j.advwatres.2003.12.001
Levia DF, Van Stan JT, Mage SM, Kelley-Hauske PW (2010) Temporal variability of stemflow volume in a beech-yellow poplar forest in relation to tree species and size. J Hydrol 380(1–2):112–120. https://doi.org/10.1016/j.jhydrol.2009.10.028
Levia DF Jr, Herwitz SR (2000) Physical properties of water in relation to stemflow leachate dynamics: implications for nutrient cycling. Can J For Res 30(4):662–666
Leyton L (1967) Rainfall interception in forest and moorland. In: International symposium on forest hydrology. Pergamon, pp 163–178
Li J, Gilhooly WP, Okin GS, Blackwell J (2017) Abiotic processes are insufficient for fertile island development: A 10-year artificial shrub experiment in a desert grassland. Geophys Res Lett 44(5):2245–2253
Li X-Y, Yang Z-P, Li Y-T, Lin H (2009) Connecting ecohydrology and hydropedology in desert shrubs: stemflow as a source of preferential flow in soils. Hydrol Earth Syst Sci 13(7):1133–1144
Link TE, Unsworth M, Marks D (2004) The dynamics of rainfall interception by a seasonal temperate rainforest. Agric For Meteorol 124(3–4):171–191. https://doi.org/10.1016/j.agrformet.2004.01.010
Liu Y, Li X, Chen G, Li M, Liu M, Liu D (2015) Epidermal micromorphology and mesophyll structure of Populus euphratica heteromorphic leaves at different development stages. PLoS ONE 10(9):e0137701
Livesley SJ, Baudinette B, Glover D (2014) Rainfall interception and stem flow by eucalypt street trees: the impacts of canopy density and bark type. Urban For Urban Green 13(1):192–197. https://doi.org/10.1016/j.ufug.2013.09.001
Llorens P, Poch R, Latron J, Gallart F (1997) Rainfall interception by a Pinus sylvestris forest patch overgrown in a Mediterranean mountainous abandoned area I. Monitoring design and results down to the event scale. J Hydrol 199(3–4):331–345
Loritz R, Gupta H, Jackisch C, Westhoff M, Kleidon A, Ehret U, Zehe E (2018) On the dynamic nature of hydrological similarity. Hydrol Earth Syst Sci 22(7):3663–3684
Lundberg A, Calder I, Harding R (1998) Evaporation of intercepted snow: measurement and modelling. J Hydrol 206(3–4):151–163
Lundberg A, Eriksson M, Halldin S, Kellner E, Seibert J (1997) New approach to the measurement of interception evaporation. J Atmos Oceanic Technol 14(5):1023–1035
Lundberg A, Halldin S (2001) Snow interception evaporation. Review of measurementtechniques, processes, and models. Theor Appl Climatol 70(1–4):117–133
Ma L, Teng Y, Shangguan Z (2014) Ecohydrological responses to secondary natural Populus davidiana and plantation Pinus tabulaeformis woodlands on the Loess Plateau of China. Ecohydrology 7(2):612–621
Mahat V, Tarboton DG (2014) Representation of canopy snow interception, unloading and melt in a parsimonious snowmelt model. Hydrol Process 28(26):6320–6336
Mahendrappa M (1974) Chemical composition of stemflow from some eastern Canadian tree species. Can J For Res 4(1):1–7
Mahendrappa M (1990) Partitioning of rainwater and chemicals into throughfall and stemflow in different forest stands. For Ecol Manage 30(1–4):65–72
Majima M, Tase N (1982) Spatial variation of rainfall in a red pine forest. Bull Environ Res Cen Univ Tsukuba 6:75–82
Malone M (2015) Hydrological and biogeochemical fluxes of throughfall and stemflow in temperate swamps
Manfroi OJ, Kuraji K, Suzuki M, Tanaka N, Kume T, Nakagawa M, To Kumagai, Nakashizuka T (2006) Comparison of conventionally observed interception evaporation in a 100-m2 subplot with that estimated in a 4-ha area of the same Bornean lowland tropical forest. J Hydrol 329(1–2):329–349. https://doi.org/10.1016/j.jhydrol.2006.02.020
Martinez-Meza E, Whitford WG (1996) Stemflow, throughfall and channelization of stemflow by roots in three Chihuahuan desert shrubs. J Arid Environ 32(3):271–287
Masukata H, Ando M, Ogawa H (1990) Throughfall, stemflow and interception of rainwater in an evergreen broadleaved forest. Ecol Res 5(3):303–316
Mathers T, Taylor C (1983) Rainfall interception on a small forested watershed within the Kawartha Lakes region. Can Water Res J 8(1):120–129
McJannet D, Wallace J, Reddell P (2007) Precipitation interception in Australian tropical rainforests: I. Measurement of stemflow, throughfall and cloud interception. Hydrol Process Int J 21(13):1692–1702
McKee AJ, Carlyle-Moses DE (2016) Modelling stemflow production by juvenile lodgepole pine (Pinus contorta var. latifolia) trees. J For Res 28(3):565–576. https://doi.org/10.1007/s11676-016-0336-9
Michalzik B (2011) Insects, infestations, and nutrient fluxes. In: Forest hydrology and biogeochemistry. Springer, pp 557–580
Miller DH (1966) Transport of intercepted snow from trees during snow storms. Res Paper PSW-RP-033 Berkeley, Ca: US Department of Agriculture, Forest Service, Pacific Southwest Forest & Range Experiment Station 30, p 33
Miralles D, De Jeu R, Gash J, Holmes T, Dolman A (2011) Magnitude and variability of land evaporation and its components at the global scale
Mitchell PJ, Lane PN, Benyon RG (2012) Capturing within catchment variation in evapotranspiration from montane forests using LiDAR canopy profiles with measured and modelled fluxes of water. Ecohydrology 5(6):708–720
Molchanov AA (1963) The hydrological role of forests
Molina AJ, del Campo AD (2012) The effects of experimental thinning on throughfall and stemflow: a contribution towards hydrology-oriented silviculture in Aleppo pine plantations. For Ecol Manage 269:206–213
Moore LD, Van Stan JT, Gay TE, Rosier C, Wu T (2016) Alteration of soil chitinolytic bacterial and ammonia oxidizing archaeal community diversity by rainwater redistribution in an epiphyte-laden Quercus virginiana canopy. Soil Biol Biochem 100:33–41. https://doi.org/10.1016/j.soilbio.2016.05.016
Moore TR (2003) Dissolved organic carbon in a northern boreal landscape. Glob Biogeochem Cycles 17(4). https://doi.org/10.1029/2003gb002050
Mosello R, Brizzio MC, Kotzias D, Marchetto A, Rembges D, Tartari G (2002) The chemistry of atmospheric deposition in Italy in the framework of the National Programme for Forest Ecosystems Control (CONECOFOR). J Limnol 61(1s):77. https://doi.org/10.4081/jlimnol.2002.s1.77
Mongeon P, Paul-Hus A (2016) The journal coverage of Web of Science and Scopus: a comparative analysis. Scientometrics 106(1):213–228
Murray S, Watson I, Prentice I (2013) The use of dynamic global vegetation models for simulating hydrology and the potential integration of satellite observations. Prog Phys Geogr 37(1):63–97
Murray SJ (2014) Trends in 20th century global rainfall interception as simulated by a dynamic global vegetation model: implications for global water resources. Ecohydrology 7(1):102–114. https://doi.org/10.1002/eco.1325
Nanko K, Hotta N, Suzuki M (2006) Evaluating the influence of canopy species and meteorological factors on throughfall drop size distribution. J Hydrol 329(3–4):422–431
Nasiri M, Zare N, Jalilvand H (2012) Investigation of the effective factors on rate of stemflow for tree species in Hyrcanian forests. Egypt J Biol 14(1):37–44
Návar J (2017) Fitting rainfall interception models to forest ecosystems of Mexico. J Hydrol 548:458–470. https://doi.org/10.1016/j.jhydrol.2017.03.025
Neal C, Robson A, Bhardwaj C, Conway T, Jeffery H, Neal M, Ryland G, Smith C, Walls J (1993) Relationships between precipitation, stemflow and throughfall for a lowland beech plantation, Black Wood, Hampshire, southern England: findings on interception at a forest edge and the effects of storm damage. J Hydrol 146:221–233
Nezamdoost H, Sefidi K, Rasoulzadeh A, Sadeghi S (2018) Quantifying throughfall, stemflow, and rainfall interception in a Fagus orientalis forest and a Picea abies plantation in Siahkal, Gilan. Iran J For 9(3)
Nieschulze J, Erasmi S, Dietz J, Hölscher D (2009) Satellite-based prediction of rainfall interception by tropical forest stands of a human-dominated landscape in Central Sulawesi, Indonesia. J Hydrol 364(3–4):227–235
Nihlgård B (1970) Precipitation, its chemical composition and effect on soil water in a beech and a spruce forest in south Sweden. Oikos:208–217
Noirfalise A (1958) Sur l’interception de la pluie par le couvert dans quelques forêts belges. Bullet Soc For Belgium 66(10):433–439
Onodera S-I, Van Stan JT (2011) Effect of forest fires on hydrology and biogeochemistry of watersheds. In: Forest hydrology and biogeochemistry. Springer, pp 599–621
Oyarzún CE, Godoy R, De Schrijver A, Staelens J, Lust N (2004) Water chemistry and nutrient budgets in an undisturbed evergreen rainforest of southern Chile. Biogeochemistry 71(1):107–123
Page C (1976) The taxonomy and phytogeography of bracken—a review. Bot J Linn Soc 73(1–3):1–34
Paltineanu I, Starr J (2000) Preferential water flow through corn canopy and soil water dynamics across rows. Soil Sci Soc Am J 64(1):44–54
Peterson DL, Rolfe GL (1982) Precipitation components as nutrient pathways in floodplain and upland forests of central Illinois. For Sci 28(2):321–332
Petit F, Kalombo K (1984) L’interception des pluies par différents types de couverts forestiers. Bulletin de la Société Géographique de Liège:99–127
Porada P, Van Stan JT, Kleidon A (2018) Significant contribution of non-vascular vegetation to global rainfall interception. Nat Geosci 11(8):563
Pound P (2017) Quantification and characterization of net precipitation bacterial flux from a subtropical epiphyte-Laden oak forest. Georgia Southern University
Price A, Dunham K, Carleton T, Band L (1997) Variability of water fluxes through the black spruce (Picea mariana) canopy and feather moss (Pleurozium schreberi) carpet in the boreal forest of Northern Manitoba. J Hydrol 196(1–4):310–323
Price AG, Carlyle-Moses DE (2003) Measurement and modelling of growing-season canopy water fluxes in a mature mixed deciduous forest stand, southern Ontario, Canada. Agric For Meteorol 119(1–2):69–85. https://doi.org/10.1016/s0168-1923(03)00117-5
Price AG, Watters RJ (1989) The influence of the overstory, understory and upper soil horizons on the fluxes of some ions in a mixed deciduous forest. J Hydrol 109(1–2):185–197
Pryor S, Barthelmie R (2005) Liquid and chemical fluxes in precipitation, throughfall and stemflow: observations from a deciduous forest and a red pine plantation in the midwestern USA. Water Air Soil Pollut 163(1–4):203–227
Pypker TG, Levia DF, Staelens J, Van Stan JT (2011) Canopy structure in relation to hydrological and biogeochemical fluxes. In: Forest hydrology and biogeochemistry. Springer, pp 371–388
Rosado BHP, Holder CD (2013) The significance of leaf water repellency in ecohydrological research: a review. Ecohydrology 6(1):150–161. https://doi.org/10.1002/eco.1340
Rowe PB, Hendrix T (1951) Interception of rain and snow by second-growth ponderosa pine. Eos, Trans Am Geophys Union 32(6):903–908
Sadeghaen S, Shafieajbishe R, Rafati M, Shahriari D (2002) Technical evaluations of micro irrigation systems and assessing their application in deficit irrigation and compared with surface irrigation on tomato. Iranian Ministry of Agricultural Research and Education Organization. Varamin Agrifultural Research Center
Sadeghi SMM, Attarod P, Van Stan JT, Pypker TG (2016) The importance of considering rainfall partitioning in afforestation initiatives in semiarid climates: a comparison of common planted tree species in Tehran, Iran. Sci Total Environ 568:845–855. https://doi.org/10.1016/j.scitotenv.2016.06.048
Sadeghi SMM, Attarod P, Van Stan JT, Pypker TG, Dunkerley D (2015) Efficiency of the reformulated Gash’s interception model in semiarid afforestations. Agric For Meteorol 201:76–85. https://doi.org/10.1016/j.agrformet.2014.10.006
Sadeghi SMM, Van Stan JT, Pypker TG, Friesen J (2017) Canopy hydrometeorological dynamics across a chronosequence of a globally invasive species, Ailanthus altissima (Mill., tree of heaven). Agric For Meteorol 240–241:10–17. https://doi.org/10.1016/j.agrformet.2017.03.017
Sadeghi SMM, Van Stan JT, Pypker TG, Tamjidi J, Friesen J, Farahnaklangroudi M (2018) Importance of transitional leaf states in canopy rainfall partitioning dynamics. Eur J Forest Res 137(1):121–130
Schooling JT, Carlyle-Moses DE (2015) The influence of rainfall depth class and deciduous tree traits on stemflow production in an urban park. Urban Ecosyst 18(4):1261–1284. https://doi.org/10.1007/s11252-015-0441-0
Schooling JT, Levia DF, Carlyle-Moses DE, Dowtin AL, Brewer SE, Donkor KK, Borden SA, Grzybowski AA (2017) Stemflow chemistry in relation to tree size: a preliminary investigation of eleven urban park trees in British Columbia, Canada. Urban For Urban Green 21:129–133. https://doi.org/10.1016/j.ufug.2016.11.013
Schumacher J, Christiansen JR (2015) Forest canopy water fluxes can be estimated using canopy structure metrics derived from airborne light detection and ranging (LiDAR). Agric For Meteorol 203:131–141. https://doi.org/10.1016/j.agrformet.2014.12.007
Seastedt T (1985) Canopy interception of nitrogen in bulk precipitation by annually burned and unburned tallgrass prairie. Oecologia 66(1):88–92
Shen X, Anagnostou EN (2017) A framework to improve hyper-resolution hydrological simulation in snow-affected regions. J Hydrol 552:1–12
Shure DJ, Lewis AJ (1973) Dew formation and stem flow on common ragweed (Ambrosia artemisiifolia). Ecology 54(5):1152–1155
Šraj M, Brilly M, Mikoš M (2008) Rainfall interception by two deciduous Mediterranean forests of contrasting stature in Slovenia. Agric For Meteorol 148(1):121–134
Staelens J, De Schrijver A, Verheyen K (2007) Seasonal variation in throughfall and stemflow chemistry beneath a European beech (Fagus sylvatica) tree in relation to canopy phenology. Can J For Res 37(8):1359–1372. https://doi.org/10.1139/x07-003
Staelens J, De Schrijver A, Verheyen K, Verhoest NEC (2008) Rainfall partitioning into throughfall, stemflow, and interception within a single beech (Fagus sylvatica L.) canopy: influence of foliation, rain event characteristics, and meteorology. Hydrol Process 22(1):33–45. https://doi.org/10.1002/hyp.6610
Sun X, Onda Y, Kato H (2014) Incident rainfall partitioning and canopy interception modeling for an abandoned Japanese cypress stand. J For Res 19(3):317–328
Sun Z, Li Z, Li B, Sun T, Wang H (2017) Factors influencing corn canopy throughfall at the row scale in Northeast China. Agron J 109(4):1591–1601
Suttie JM, Reynolds SG, Batello C (2005) Grasslands of the World, vol 34. Food & Agriculture Org
Suzuki M, Kato H, Tani M, Fukushima Y (1979) Throughfall, stemflow and rainfall interception in Kiryu Experimental Catchment (I). J Japan For Soc 61(6):202–210
Thimonier A (1998) Measurement of atmospheric deposition under forest canopies: some recommendations for equipment and sampling design. Environ Monit Assess 52(3):353–387
Toba T, Ohta T (2005) An observational study of the factors that influence interception loss in boreal and temperate forests. J Hydrol 313(3–4):208–220. https://doi.org/10.1016/j.jhydrol.2005.03.003
Tobón Marin C, Bouten W, Sevink J (2000) Gross rainfall and its partitioning into throughfall, stemflow and evaporation of intercepted water in four forest ecosystems in western Amazonia. J Hydrol 237(1–2):40–57
Tsakov H, Alexandrov A (2005) Growth of Robinia pseudoacacia L. on a reclaimed terrain in Bulgaria studied over a period of climatic anomalies. Folia Oecologica 32(1):1–5
Uehara Y, Kume A, Chiwa M, Honoki H, Zhang J, Watanabe K (2015) Atmospheric deposition and interactions with Pinus pumila Regal canopy on Mount Tateyama in the Northern Japanese Alps. Arct Antarct Alp Res 47(2):389–399
Uyttendaele GYP, Iroumé A (2002) The solute budget of a forest catchment and solute fluxes within a Pinus radiata and a secondary native forest site, southern Chile. Hydrol Process 16(13):2521–2536. https://doi.org/10.1002/hyp.1046
Van Elewijck L (1989) Influence of leaf and branch slope on stemflow amount. CATENA 16(4–5):525–533
Van Stan II JT (2012) Controls and dynamics of canopy-derived dissolved organic matter from co-dominant broadleaved deciduous canopies to the soil of a temperate catchment in the northeastern United States. University of Delaware
Van Stan II JT, Underwood SJ, Friesen J (2018) Urban Forestry: An underutilized tool in water management. In: Friesen J, Rodriguez-Sinobas L (eds) Advanced tools for integrated water resources management, vol 3. Advances in chemical pollution, environmental management and protection. Elsevier, London, United Kingdom, pp 35–62. https://doi.org/10.1016/bs.apmp.2018.04.003
Van Stan II JT, Pypker TG (2015) A review and evaluation of forest canopy epiphyte roles in the partitioning and chemical alteration of precipitation. Sci Total Environ 536:813–824. https://doi.org/10.1016/j.scitotenv.2015.07.134
Van Stan II JT, Van Stan JH, Levia Jr. DF (2014) Meteorological influences on stemflow generation across diameter size classes of two morphologically distinct deciduous species. Int J Biometeorol 58(10):2059–2069. https://doi.org/10.1007/s00484-014-0807-7
Van Stan JT, Gay TE, Lewis ES (2016a) Use of multiple correspondence analysis (MCA) to identify interactive meteorological conditions affecting relative throughfall. J Hydrol 533:452–460. https://doi.org/10.1016/j.jhydrol.2015.12.039
Van Stan JT, Gordon DA (2018) Mini-review: stemflow as a resource limitation to near-stem soils. Front Plant Sci. https://doi.org/10.3389/fpls.2018.00248
Van Stan JT, Levia Jr DF (2010) Inter and intraspecific variation of stemflow production from Fagus grandifolia Ehrh. (American beech) and Liriodendron tulipifera L. (yellow poplar) in relation to bark microrelief in the eastern United States. Ecohydrol Ecosyst Land Water Process Interact Ecohydrogeomorphol 3(1):11–19
Van Stan JT, Lewis ES, Hildebrandt A, Rebmann C, Friesen J (2016b) Impact of interacting bark structure and rainfall conditions on stemflow variability in a temperate beech-oak forest, central Germany. Hydrol Sci J 61(11):2071–2083. https://doi.org/10.1080/02626667.2015.1083104
Van Stan JT, Wagner S, Guillemette F, Whitetree A, Lewis J, Silva L, Stubbins A (2017) Temporal dynamics in the concentration, flux, and optical properties of tree-derived dissolved organic matter in an epiphyte-laden oak-cedar forest. J Geophys Res Biogeosci 122(11):2982–2997. https://doi.org/10.1002/2017jg004111
Varhola A, Coops NC, Weiler M, Moore RD (2010) Forest canopy effects on snow accumulation and ablation: an integrative review of empirical results. J Hydrol 392(3–4):219–233
Veatch W, Brooks P, Gustafson J, Molotch N (2009) Quantifying the effects of forest canopy cover on net snow accumulation at a continental, mid-latitude site. Ecohydrology 2(2):115–128
Verry ES, Timmons D (1977) Precipitation nutrients in the open and under two forests in Minnesota. Can J For Res 7(1):112–119
Voigt G, Zwolinski M (1964) Absorption of stemflow by bark of young red and white pines. For Sci 10(3):277–282
Voss S, Zimmermann B, Zimmermann A (2016) Detecting spatial structures in throughfall data: the effect of extent, sample size, sampling design, and variogram estimation method. J Hydrol 540:527–537. https://doi.org/10.1016/j.jhydrol.2016.06.042
Wan SQ, Chen LZ (2000) Characteristics of precipitation and forest stem flow of Dongling mountainous area. Acta Ecol Sin 20(1):61–67
Wheater H, Langan S, Miller J, Ferrier R (1987) The determination of hydrological flow paths and associated hydrochemistry in forested catchments in central Scotland. In: Proceedings of the Vancouver symposium. International Association of Hydrological Sciences (IAHS)
Whitford WG, Anderson J, Rice PM (1997) Stemflow contribution to the ‘fertile island’effect in creosotebush, Larrea tridentata. J Arid Environ 35(3):451–457
Xiao Q, McPherson EG (2011) Rainfall interception of three trees in Oakland, California. Urban Ecosyst 14(4):755–769
Yankine SA, Van Stan J, Mesta DC, Côté J-F, Hildebrandt A, Friesen J, Maldonado G (2017) What controls stemflow? A LiDAR-based investigation of individual tree canopy structure, neighborhood conditions, and meteorological factors. In: AGU Fall Meeting Abstracts
Yarie J (1980) The role of understory vegetation in the nutrient cycle of forested ecosystems in the mountain hemlock biogeoclimatic zone. Ecology 61(6):1498–1514
Young JA, Evans RA, Easi DA (1984) Stem flow on western juniper (Juniperus occidentalis) trees. Weed Sci 32(3):320–327
Yuan C, Gao G, Fu B (2016) Stemflow of a xerophytic shrub (Salix psammophila) in northern China: implication for beneficial branch architecture to produce stemflow. J Hydrol 539:577–588
Yue X-f, Cui J-y, Zhang T-h, Wang S-k, Lian J, Wang X-y, Yun J-y (2014) Characteristics of rainfall interception and redistribution for Salix gordejevii in Horqin Sandy Land, Northeast China. Acta Pratacultuae Sinica 22(6):46–52
Zabret K, Šraj M (2015) Can urban trees reduce the impact of climate change on storm runoff? Urbani Izziv 26:S165–S178
Zehe E, Ehret U, Pfister L, Blume T, Schröder B, Westhoff M, Jackisch C, Schymanski S, Weiler M, Schulz K (2014) HESS opinions: functional units: a novel framework to explore the link between spatial organization and hydrological functioning of intermediate scale catchments. Hydrol Earth Syst Sci Discuss 11(3)
Zehe E, Graeff T, Morgner M, Bauer A, Bronstert A (2010) Plot and field scale soil moisture dynamics and subsurface wetness control on runoff generation in a headwater in the Ore Mountains. Hydrol Earth Syst Sci 14(6):873
Zhang Y-F, Wang X-P, Hu R, Pan Y-X (2018) Meteorological influences on process-based spatial-temporal pattern of throughfall of a xerophytic shrub in arid lands of northern China. Sci Total Environ 619:1003–1013
Zheng J, Fan J, Zhang F, Yan S, Xiang Y (2018) Rainfall partitioning into throughfall, stemflow and interception loss by maize canopy on the semi-arid Loess Plateau of China. Agric Water Manag 195:25–36
Zimmermann A, Zimmermann B (2014) Requirements for throughfall monitoring: the roles of temporal scale and canopy complexity. Agric For Meteorol 189:125–139
Zimmermann A, Zimmermann B, Elsenbeer H (2009) Rainfall redistribution in a tropical forest: spatial and temporal patterns. Water Resour Res 45(11). https://doi.org/10.1029/2008wr007470
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Appendix A
Appendix A
Canopy height-to-width ratios (H:W) and mean stemflow values in Fig. 4.7b.
Genus/spp | H:W | Stemflow | Citations |
---|---|---|---|
(–) | (–) | (% rain) | (–) |
Acer | 1.3 | 2.0 | Courchesne and Hendershot (1988), Mahendrappa (1974), Malone (2015), Schooling and Carlyle-Moses (2015), Schooling et al. (2017) |
Big-leaf maple | 3.0 | 7.0 | Hamdan and Schmidt (2012) |
Ailanthus | 3.6 | 7.2 | Sadeghi et al. (2017) |
Betula | 1.4 | 2.9 | Abrahamsen et al. (1977), Courchesne and Hendershot (1988), Molchanov (1963), Wan and Chen (2000), Zabret and Šraj (2015) |
Carya | 1.1 | 0.9 | Peterson and Rolfe (1982) |
Catalpa | 1.0 | 0.4 | Schooling and Carlyle-Moses (2015) |
Cercis | 0.9 | 0.8 | Peterson and Rolfe (1982) |
Chamaecyparis | 17.8 | 10.6 | Sun et al. (2014) |
Cupressus | 10.5 | 9.6 | Nasiri et al. (2012), Sadeghi et al. (2016), Suzuki et al. (1979) |
Fagus | 1.3 | 3.7 | Chang and Matzner (2000), Ghorbani and Rahmani (2009), Krämer and Hölscher (2009), Mosello et al. (2002), Neal et al. (1993), Noirfalise (1958), Petit and Kalombo (1984), Schooling and Carlyle-Moses (2015), Schooling et al. (2017), Staelens et al. (2008), Van Stan II (2012) |
Fraxinus | 1.3 | 1.4 | Malone (2015) |
Gleditsia | 1.1 | 0.6 | Schooling and Carlyle-Moses (2015) |
Ilex | 1.4 | 5.2 | |
Juglans | 1.0 | 1.0 | Lazerjan (2012) |
Juniperus | 0.9 | 2.4 | Badri and Gauquelin (1998), Van Stan et al. (2017), Young et al. (1984) |
Liquidambar | 1.5 | 4.1 | Xiao and McPherson (2011) |
Picea | 1.7 | 4.4 | Aussenac (1968), Bergkvist and Folkeson (1995), Cape et al. (1991), Johnson (1990), Mahendrappa (1974), Nihlgård (1970), Wheater et al. (1987) |
Pinus | 1.6 | 5.0 | Bryant et al. (2005), Cape et al. (1991), Crockford and Richardson (2000), Foster (1974), Ibrahim et al. (1982), Lawson (1967), Lei et al. (1994a, b), Mahendrappa (1974), Majima and Tase (1982), Pryor and Barthelmie (2005), Sadeghi et al. (2016), Toba and Ohta (2005), Uyttendaele and Iroumé (2002) |
Pinus (juvenile) | 2.0 | 4.4 | McKee and Carlyle-Moses (2016) *Assumed 1-m bole to bottom of H |
Platanus | 1.0 | 0.2 | Peterson and Rolfe (1982) |
Populus | 1.4 | 3.9 | Freedman and Prager (1986), Ma et al. (2014), Mahendrappa (1974), Molchanov (1963), Moore (2003), Verry and Timmons (1977) |
Prunus | 1.2 | 1.0 | Schooling and Carlyle-Moses (2015) |
Quercus | 1.1 | 1.6 | Pound (2017) |
Robinia | 1.1 | 1.6 | |
Salix | 1.3 | 3.3 | Li et al. (2009), Schooling and Carlyle-Moses (2015), Yuan et al. (2016), Yue et al. (2014) |
Thuja | 2.5 | 6.1 | Mathers and Taylor (1983) |
Tilia | 1.1 | 1.5 | Schooling and Carlyle-Moses (2015) |
Erica | 2.9 | 6.5 | Aboal et al. (1999) |
Prestoea | 6.5 | 9.8 | Frangi and Lugo (1985) *W = 2.6 m from landscaping manual |
Nothofagus | 8.2 | 10.2 |
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Sadeghi, S.M.M., Gordon, D.A., Van Stan II, J.T. (2020). A Global Synthesis of Throughfall and Stemflow Hydrometeorology . In: Van Stan, II, J., Gutmann, E., Friesen, J. (eds) Precipitation Partitioning by Vegetation. Springer, Cham. https://doi.org/10.1007/978-3-030-29702-2_4
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